1. SONET is used as a WAN. ANSI standard – SONET ITU-T standard – SDH Both are fundamentally similar and compatible.

2. Architecture Defines a hierarchy of electrical signaling levels called Synchronous Transport Signal. Corresponding optical signals are called Optical Carriers. In SDH it is called Synchronous Transport Module.

4. SONET Devices STS Multiplexer / Demultiplexer Regenerator – Extend the length of the link Add / Drop Multiplexer – can add STSs coming from multiple sources into a given path or can remove a given signal from a path and redirect it Terminals

6. Connections Sections – connecting neighbouring devices Lines – between two multiplexers Paths – end –to-end portion of the network

7. SONET Layers Path layer – optical source to optical destination Line layer – movement of signal across the line Section layer - movement of signal across the section. It handles Framing, Scrambling and Error Control POH. LOH and SOH is added to the frame Photonic layer – physical specifications of optical fiber, sensitivity of the receiver, multiplexing functions etc. SONET uses NRZ encoding with presence of light representing 1 and absence of light representing 0

8. SONET Layers

10. SONET Frames Each STS – n frame is composed of 9 rows and 90 columns It is transmitted at a fixed rate of 8000 frames per second. Each byte in a SONET frame can carry a digitized voice channel.

13. SONET Frames The data rate of an STS – n signal is n times the data rate of an STS-1 signal The duration of any frame is 125µs

14. STS-1 frame overheads

15. STS-1 Section overhead

16. Line overhead

17. Path overhead

18. Section overhead is calculated for each SONET device (Regenerators and Multiplexers) Path overhead is calculated for end-to-end devices

19. Overhead Summary E2

20. Encapsulation SPE need to be encapsulated in an STS-1 frame. SONET allows one SPE to span two frames H1 and H2 pointers define the beginning of the SPE These pointers are located in the line overhead because encapsulation occurs at a multiplexer

23. What are the values of H1 and H2 if the SPE starts at byte number 650? 650 = 0x028A H1 = 0x02 H2 = 0x8A H3 byte is used for justification

24. STS Multiplexing Multiplexing is Synchronous TDM All clocks in the network are locked to a master clock to achieve synchronization. 4 STS-3 signals can be multiplexed into one STS-12 signal. However STS-3 signals need to be first demultiplexed into 12 STS-1 signals and then these 12 signals need to be multiplexed into an STS-12 signal

26. Byte interleaving

27. A byte in an STS-1 frame keeps it row position but changes its column position. Demultiplexing is easier than in statistical TDM. Demultiplexing deals only with the position of the byte, not its function. Byte Interleaving preserves the Section and Line overheads. This may not be true with Path overheads.

29. Concatenated Signal In normal operation –an STS-n signal is made of n STS-1 signals If we have a signal with a data rate higher than an STS-1 signal – SONET consider that as one concatenated STS-n signal. Eg : STS3c Here only 9 bytes of path overhead and 260 columns can be used for data.

31. Add / Drop Multiplexer It replaces a signal with another one. It operates at the line layer. Does not create any overheads. It acts as a switch. It removes one type of signal and adds same type of signal. It simply replaces the corresponding bytes with new bytes.

33. SONET Networks Using SONET equipment we can create a SONET Network. Used as a high speed backbone carrying data from different networks (like IP or ATM)

35. Linear Networks Point-to-Point Networks Made up os STS Multiplexer, STS Demultiplexer and zero or more regenerators. No ADMs. Signal flow can be unidirectional or bidirectional.

36. Unidirectional Point-to-Point Network

37. Multipoint Networks Uses ADMs to allow communication between Terminals. Each terminal can send data to one or more downstream terminals. It can be Bidirectional also.

38. Unidirectional Multipoint SONET network

39. Automatic Protection Switching (APS) Linear networks defines APS to create protection against failure. It is defined at the Line layer. Idea is to provide redundancy. Main line is referred to as the Work Line and the redundant line as the Protection Line. There are Three schemes.

40. APS in Linear Networks One-Plus-One APS: Normally two lines – both are active all the time. Receiving Multiplexer selects from the line with better quality. Failure recovery is instantaneous but inefficient. It is done at the Path layer.

41. APS in Linear Networks One-to-One APS: Normally two lines – data sent on working line until it fails. At that time receiver uses the reverse channel to inform the sender Failure recovery is slower than that of one- plus-one scheme More efficient It is done at the Line layer.

42. APS in Linear Networks One-to-many APS: It is similar to One-to-One except there is only one protection line for many working lines.. Not as secure as One-to-One. It is done at the Line layer.

43. APS in Linear Networks

44. Ring Networks Unidirectional Path Switching Ring: 2 rings, one working ring and one protection ring. Idea is similar to one-plus-one APS Same signal flows in both rings in different directions. Receiver selects from the ring with better quality. Failure recovery is instantaneous but inefficient. Maintenance is done at the Path layer.

45. Ring Networks

46. Bidirectional Line Switching Ring: 2 rings for working line and two for protection line, so 4 rings. Idea is similar to one-to-one APS If a working ring fails the receiver uses the reverse channel to inform the upstream node to use protection ring.. Failure recovery in different situations is possible. Failure discovery is done at the Line layer by ADMs.

47. Ring Networks

48. Combination of Rings

49. Mesh Networks Problem with Ring networks is lack of Scalability. To upgrade we need to upgrade lines as well as ADMs. For better performance we go for Mesh Networks.

50. Mesh Networks Here a switch is called a cross-connect with input and output ports. Input port – takes OC-n, changes to STS- n, demultiplexes into STS-1 signals and give to output port. Output port – takes STS-1 signals, multiplexes to STS-n signals and makes an OC-n for transmission.

51. Mesh Networks

52. Virtual Tributaries Designed for Backward compatibility It is a partial payload that can be inserted into an STS-1 and combined with other partial payloads to fill out the fram.

53. Virtual Tributaries

54. Types of VTs Four Types Number of columns varies Interleaved column by column

55. Types of VTs

56. THANK YOU